KR940006725B1 - Rear projection screen - Google Patents

Abstract

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Description

Rear projection screen

1 is a perspective view of the rear projection screen of the present invention used in a rear projection color xpf revision apparatus.

2 is an enlarged perspective cross-sectional view of a portion of the lenticular lens array used in a preferred embodiment of the rear projection screen of the present invention.

3 is a cross-sectional view taken along line 3-3 of the lenticular lens array of FIG.

4 is an enlarged cross-sectional view of the tip portion of the lenticular lens shown in FIG.

FIG. 5 is a cross-sectional view showing an example of light beams passing from the projection light source toward the observation plane, the same tip as in FIG. 3 of the lenticular lens according to the present invention.

6 is a cross-sectional view showing an example of ambient light incident on the tip of the lenticular lens array of FIG. 3 according to the present invention.

* Explanation of symbols for main parts of the drawings

10: rear projection color television system 12: projection screen

32: Lenticular Lens

The present invention relates to the construction of a rear projection screen, which receives a beam of light from an image source and deflects each beam to display an image with a substantially uniform brightness over a wide viewing angle. Light spreading means are provided at the front of the screen, which generally comprises a plurality of parallel lenticular lenses positioned in close proximity, at least some of which are lenticular lenses. And a base portion, a first side portion, a second side portion, and a tip portion facing the first side portion.

Rear projection screens include projection rayta displays, flight simulators, avionics displays, traffic lights, micro film readers, video games, projection video monitors, and rear projection film media displays that produce user observable displays. It is used in many different types of equipment. In this application, an image source located behind the screen projects light along the projection axis towards the screen to form an image at the surface of the screen, which is distributed to the viewer on the front side of the screen.

In the case where there are a large number of observers, it is preferable to distribute the light at a large horizontal angle because these observers are usually wide in the horizontal direction. This is particularly desirable for rear screen projection television receivers where a large number of observers are usually present and seated at relatively wide horizontal angles relative to the screen.

One problem with this rear projection system is that more light energy is projected along the projection axis than anywhere else, so that the closer the viewer is to the projection side, the brighter the viewer can see the image. Back Screen Projection Color video units typically project each primary color image onto the screen through separate projection lenses using three cathode ray tubes that each share three primary colors of red, green, and blue. In a horizontal arrangement of a typical cathode ray tube, the cathode ray tube is usually located at the center along the projection axis, and the red and blue cathode ray tubes are located at optical axes offset from 5 to 10 degrees with respect to the green optical axis, respectively. These offsets cause a phenomenon known as color deviation if not corrected by the screen. In other words, if the luminance of the red, green, and blue light is normalized with respect to the center of the observer, the ratio of the luminance will change with each position throughout the horizontal viewing plane. As such, the viewer's perception of the image is determined by the viewer's horizontal position with respect to the screen.

Further, when the rear projection screen is exposed to external light, the contrast of the projected image is affected by the reflection of the external light on the surface side of the screen, so it is desirable to reduce the reflection of such external light on the surface side of the screen. For this reason, various masking techniques in which an antireflective black surface is inserted between lenticular lenses constituting the rear projection screen have been proposed as external light reflection reduction measures.

Various rear projection screens have been proposed to increase the horizontal viewing angle range. William R. One such system, described in US Patent No. 3,578,841 to Mr. Elmer, is a rear surface, such as a Fresnel lens, which focuses light from an image source into parallel rays, and over a specified horizontal viewing angle. A screen having a front surface constituted by vertically ribbed diffused lenses that diffuse light across is utilized. The shape of the vertical ribs of the diffusion lens is set by an equation determined by the desired diffusion angle from the center line. However, ribs drawn according to these equations are observed by disposing these ribs between a pair of side ribs that are significantly inefficient and rapidly pointed when light is diffused over an angle of 60 ° or more, i.e., 30 ° or more on either side of the centerline. It is necessary to increase the angle by more than 90 °, that is, by 45 ° on both sides of the center line.

Another type of rear projection screen is described in a paper entitled "One-Piece, Ultra Wide Angle Rear Projection Screen" by Yoshito Miyatake and Yoshitomi Nagaoka, described in Japan Display, No. 587, 1983. It is. Screens of one-piece configuration, called Phase-III, typically have a cylindrical lenticular lens, which is typically a trapezoidal lenticular lens having a top surface of the same cross section as the cross section of the cylindrical lenticular, and a bilateral side that is flat and slightly inclined toward the center of the rear screen. It is arranged alternately with. According to this paper, phase-III type screens have a ± 60 ° horizontal viewing angle, but when used as a rear projection television screen, fast color deviation is likely to occur. The second screen, also referred to as Phase-IV, uses two cylindrical cylindrical trapezoidal lenticular lenses alternately with standard cylindrical lenticular lenses. A standard cylindrical lenticular lens is located between two cylindrical surfaces of the trapezoidal lenticular lens. According to this paper, with this configuration, the rapid color deviation of phase-III is reduced, while the horizontal viewing angle is relatively large. However, the resulting Phase-IV lenticular lens has a very large cross-sectional perspective, is larger than its height, and has a slightly smaller tip portion than the entire width of the lenticular lens. The possibility of implementation is limited.

The present invention relates to a back screen configuration to avoid the above disadvantages. In the projection screen according to the invention, the first side has an average slope of approximately 43 ° to 85 ° with respect to the base, and the second side has an average slope of approximately 43 ° to 85 ° with respect to the base. The first average slope and the second average slope are selected to reflect the first side portion and the second side portion inwardly, and the ratio of the height of the lenticular lens to the width of the base portion is greater than 1: 1, The ratio of the width of the base portion to the width of the tip portion is greater than 2: 1, the tip portion is adjacent to the first side portion and the second side portion, and the tip portion has two convex cylindrical portions and a central concave cylindrical portion. And the tip portion actually has refractive power.

In the rear projection screen of the present invention, both sides of the lenticular lens transmit the light from the projection light source to the tip, which preferentially accumulates the light so that the detected amount of external light reflection is not directed to the viewing surface. Tip regions comprising two convex cylindrical elements and a central concave cylindrical element of the lenticular lens array are known to exhibit exceptional diffusion of light in the horizontal direction. In addition, when two or more color circles are used in a system, such as in a color rear projection television system with three individual cathode tubes arranged horizontally, the array of lenticular lenses of the present invention has been demonstrated to minimize color deviation. Moreover, the total height-to-width ratio of the lenticular lens, as well as the tip-to-total width ratio, provides a rear projection screen that can be black masked to nearly 60% of the projection surface.

The invention will now be described in more detail with reference to the accompanying drawings.

In order to facilitate understanding of the rear projection screen of the present invention, the general apparatus and operation of the projection assembly using the rear projection screen of the present invention will be described first, and the shape of the various lens surfaces that can be used in the screen and A method for deriving these shapes will be described later.

1 shows a rear projection color television system 10 using a rear projection screen 12 constructed in accordance with the present invention. In such a device, the television video source signal is received by the television receiving circuitry 14 and the rear surface 22 of the projection screen 12 through the respective red, green and blue projection cathode ray tube assemblies 16, 18, 20. Is projected on. The three cathode ray tubes (CRTs) 16, 18 and 20 are arranged horizontally with respect to the projection axis 23 about the green CRT 18. As a result of this horizontal arrangement, the three CRTs 16, 18 and 20 have optical axes 24, 26 and 28 with angles offset from each other. Typically, the red optical axis 24 and the blue optical axis 28 are offset at an angle of 5 to 10 degrees with respect to the green optical axis 26.

The rear face 22 of the rear projection screen 12 is flat and parallel focusing, such as a friendsel lens, which focuses divergent light emitted from the projectors 16, 18, and 20 into parallel rays according to the known operating principle of the friendsel lens. The lens is installed at a right angle. The front face 30 of the screen 12 is generally planar and includes a plurality of vertical lenticular lens elements 32 positioned in close proximity. According to the present invention, the shape of the lenticular element 32 is such that light is refracted to diffuse light horizontally over a wide horizontal observation angle α in the observation surface 33.

Conventionally, rear projection screen assemblies, such as those shown in FIG. 1, utilize two-piece screens and one-piece screens due to the particular screen characteristics required. For example, the two-piece screen has the property of horizontally distributing light reasonably widely, but the resolution of the projected image is reduced, resulting in a ghost image. In addition, when the light is widely distributed horizontally by this configuration, it is necessary to precisely control the overlapping and thickness of the screen during manufacturing in order to minimize color deviation. The one-piece screen had improved characteristics but limited horizontal observation angle of about ± 30 °. In contrast, the vertical lens arrangement of the present invention can be used in one or two piece screens, and efficiently distributes light within an observation angle of ± 85 ° in the horizontal direction with perceptually uniform brightness and minimal color deviation. You can.

Referring to FIG. 2, there is shown a state in which the front surface 30 of the projection screen 12 includes a plurality of lenticular lens elements 32 parallel to each other and vertically parallel. As shown in FIG. 3, the center-to-center distance between the lenticular elements 32 is the lenticular pitch W. FIG. The lenticular pitch W of the projection screen 12 constructed in accordance with the present invention can be changed to suit a particular application without changing the performance of the screen if all dimensions of the lenticular lens element 32 are changed in the same ratio. In practice, the lenticular pitch is selected according to the overall dimensions of the screen and the required number of lenticulars in front of the screen. For example, when used in a rear projection television screen, the pitch of the lenticular lens element 32 may range from about 0.3 mm to 1.0 mm, typically for a screen with a diagonal range of about 26 inches to 72 inches. By forming the lenticular lens element 32 sufficiently precisely and closely, an observer can observe essentially smooth continuous images, just as horizontal lines on a television screen usually appear as continuous images or images from a normal viewing distance. Can be.

When constructing a lenticular lens array including the lenticular lens elements 32 of the present invention, it is preferable that adjacent elements are brought into contact with each other so that the element spacing is zero and the lenticular pitch is equal to the width of each element. In practice, however, some margin may be provided between the elements 32, but such margin may be provided in various ways, such as providing a simple radius. If such a margin is provided, the margin is preferably 1% or less of the element width.

Each lenticular lens element 32 has both side surfaces 34 and 36 and an upper tip surface 38. Both sides 34 and 36 are straight or nearly straight or convex outwardly, but the sides are preferably convex outwardly. Both sides 34 and 36 have mean slopes denoted by θ and θ ′ (FIG. 3), respectively. θ and θ ′ range from approximately 43 ° to 85 ° and are chosen to set the required internal reflectivity. According to the present invention, θ and θ 'need not be equivalent, but θ and θ are preferably larger than 70 °. When the sidewalls are formed at these angles, the light rays passing through the element 32 are incident on both side walls 34 and 36 at angles larger than the critical angle according to Snell's law, and as a result, total reflection is performed on the inner surface of the sidewall and ribs. Will pass through. It is preferable that θ and θ 'are equal and the ribs 32 are symmetrical. If θ and θ 'are not equal and the observation planes are symmetrical, the lenticular lens elements 32 on the screen observation plane 30 can be mirror image relationships with each other. Sides 34 and 36 may be configured to reflect and refract light, but are preferably configured to effect near internal reflection to direct light from the projection source to upper tip surface 38.

As shown in FIG. 4, the upper tip face 38 is preferably composed of three cylindrical faces 40, 42, 44 of equal radius. As shown, the cylindrical surfaces 40 and 44 are formed into a cylindrical convex cylindrical shape, while the cylindrical surface 42 is formed into a cylindrical concave cylindrical shape. The upper tip surface 38 may be refracted after reflecting a part of the light by reflecting the light toward the viewer, but the upper tip surface 38 is preferably configured to refract light almost to the observation surface.

The width W 'of the upper tip face 38 is determined in part by the average inclinations θ and θ' of the sides 34 and 36, in part by the refractive index of the constituent material and in part by the specific lens properties to be achieved. do. However, according to the object of the present invention to provide a lenticular lens array that distributes light over a substantially horizontal 180 ° with perceptually uniform brightness and minimal deviation, the ratio of pitch width W to height h of any lenticular lens And the ratio of tip width W 'to pitch width W are more important than others. Therefore, the ratio of height h to pitch width W of the lenticular lens is preferably larger than 1: 1, more preferably at least 3: 2, and the ratio of pitch width W to tip width W 'of the lenticular lens is 2: It is preferable that it is larger than 1, more preferably at least 3: 1.

One skilled in the art can construct a lenticular lens array using the lens element configuration described herein in combination with other lenticular lens element configurations in order to optimize the rear projection screen for a particular purpose. However, it can be seen that excellent gain and efficiency are obtained when distributing light in the rear projection screen ± 85 ° angle range composed solely of the lenticular lens elements of the configuration described herein.

The rear projection screen 12 made in accordance with the present invention can be manufactured in several manufacturing processes including compression molding, injection molding, extrusion, casting and photopolymerization processes. Such screens may be composed of optically transparent or translucent solid materials such as organic glass or various kinds of plastics. In addition, such a screen structure can also be made into the mixture of various materials. Thus, a suitable material is poly-methylemethacrylate.

The one-piece screen, which consists of two sides with optical function, can be made of two pieces suitably tied together. This one piece screen configuration has the advantages of low cost and simple manufacturing. In addition, the thickness of this screen is not critical, and no overlap of the optical pattern between the opposing surfaces of the sheet is required.

The vertical diffusion provided by the rear projection screen 12 of the present invention is relatively small. Thus, screen 12 may be provided with other types of diffusion media. This diffusing action can be provided, for example, by the volumetric properties of the photorefractive material constituting the screen, and can be provided on the surface weave of the non-front surface in the case of a back or two piece configuration, and the composite overlap It may be provided by the diffusion layer of body weight, or may also be provided in a combination of these means. This diffusion, however, usually takes the form of a Gaussian distribution, providing a longitudinal diffusion of approximately ± 10 ° until the light intensity drops by 50%, such that the longitudinal half-angle of this diffusion is approximately ± 10 °.

It should be noted here that the orientation of the lens element 32 on the front surface 30 of the rear projection screen 12 is characterized by a wide distribution of light in the horizontal direction. Therefore, by rotating the rear spray screen 12 by a desired angle, for example, 90, light can be widely distributed in the vertical direction. Further, if it is desirable to distribute light widely in the horizontal direction and the vertical direction, the rear projection screen can be configured by overlapping the array of ribs in the horizontal direction according to the present invention and the array of ribs in the vertical direction according to the present invention.

5 shows horizontal dispersion of light through a reflective refractive lenticular lens element 32 constructed in accordance with the present invention. Rays r1, r2, and r3 are incident from the projection light source, are focused by a parallel focusing lens such as a friendsel lens, become parallel rays, and are distributed by the lenticular lens element 32. The rays r1, r2, and r3 pass in a homogeneous medium of the lens element 32 and thus move in a straight line. When these light rays r1, r2, r3 enter the side surfaces 34 and 36 configured to form an internal reflection surface, these light rays are reflected, and the incident angle of the light rays becomes equal to the reflection angle. Further, when these rays r1, r2, and r3 enter the upper tip surface 38 at an angle of incidence smaller than the critical angle of the lens air interface, these rays are refracted according to Snell's law.

As described above, it is preferable that the lens element 32 is continuously adjacent to the left and right, and adjacent side surfaces 34 and 36 are adjacent to the front surface 30. Since each element 32 is spaced apart from the left and right adjacent elements, each side surface 34 and 36 forms a groove 46 resembling a "V" shape bent outward from each other. When the lens element 32 is constructed in accordance with an embodiment of the present invention in which the ratio of the total seized width W and the tip width W 'is at least 3: 1, black masking is performed on at least two thirds of the surface area of the front surface 30. It is preferable. This black masking of the rear projection screen 12 can be achieved by using black masking that retains the reflective properties of the side surfaces 34 and 36. As a method of performing such black masking, the actual portions of the grooves 46 are filled with black particles 48 capable of absorbing visible light, and the black particles 48 are formed in the grooves 46 between the ribs 32. The actual portion is filled and the black particles 48 are retained in the grooves 46 by the skin 50 extending above the grooves 46 between the ribs 32.

If the lenticular lens element 32 is configured without such black masking, the reflection of the ambient light directed to the observer can be made smaller than that of a normal one-piece screen, and the reduction of the external light reflection can be achieved by the front surface of the screen 12 ( Most of the ambient light enters into the grooved portion 46 occupying almost two thirds of the total area of 30) and is obtained by passing through the screen 12. 6 schematically illustrates the path of ambient light incident on the sides 34, 36 of rib 32. As shown, the solid line represents incident or reflected light, while the line represents the refracted light. If the material of the neutral tendency is present in the construction of the screen, the incident light is attenuated by passing through the screen, but the ambient light passing through the screen 12 and reflected from the rear surface 12 and returned through the front surface 30, It is proportional to the light beam from the projection light source and passes through the material twice or more on average, so that an image of good contrast can be provided.

If necessary, the front surface 30 can be made antireflective by weaving the front surface 30 of the screen 12 to increase the diffusibility. Depending on the degree desired, the entire front surface 30 can be woven. In addition, if the screen is masked in black, by only weaving only the upper tip surface 38 of the lens element 32, a non-reflective screen can be obtained. In addition, in the case of a black masked screen, anti-reflective coating may be applied to the exposed upper tip surface 38 to eliminate the reflected light, thereby improving the contrast of the screen.

The following example illustrates the lens element configuration according to the present invention, which provides good characteristics of the rear projection color television system. Such examples are intended to illustrate the invention and do not limit the scope of the invention. The reference coordinate point of the standard lens element is shown in FIG. 3, the coordinate origin is indicated by 0, the X-axis coordinate position increases from the lower left corner to the right, and the Y-axis coordinate position moves the image axis at the lower left corner. To increase. The lenticular element shown has a pitch of 0.55 mm and is symmetrical about a coordinate line of X = 0.275 mm. Also, all values of the Y coordinate are greater than or equal to 0, and this lens element is defined as a continuous function with respect to the slope of the coordinates Y and Y.

The side surface of each left-right symmetry is defined by 397 line segments represented by following Formula, respectively.

The terminal coordinates of the 397th line segment are X ₃₉₈ = 0.21310 and Y ₃₉₈ = 0.888438. The shape of this side surface is determined by the following interpolation method.

That is, let Y = Yi + (X−Xi) _X Mi + D for _X provided as X <0.21310 and Xi ≦ X <Xi _{+ 1} .

In addition, the shape of an upper surface is prescribed | regulated as follows.

That is, for X in the range of 0.21310≤X≤0.25735, the shape of the tip cross section is XO₁ = 0.23971mm, YO₁ = 0.86896mm in the formula of Y = -SQRT [R²- (X-XO₁) ²] + YO₁ and The shape of the tip is defined as Y = + SQRT [R²- (X-XO₂) ²] YO₂ with respect to X in the range of 0.25735≤X <0.2750 (center of the reference lenticular lens). In the form of XO₂ = 0.22750mm, YO₂ = 0.91936mm, R = 0.03076mm.

The above formula defines one aspect of a symmetric lenticular lens element constructed according to the invention with a lenticular lens of 0.55 m. As described above, the lenticular pitch can be changed without changing the characteristics of the lens by changing all other dimensions of the lens element at the same ratio. Therefore, when constructing a lenticular screen using the above-described lens element, when the adjacent lenticular lens elements are brought into contact with each other or a margin is provided between the lenticular lens elements, this margin is not more than 1% of the width of the lens element. It is preferable to use. The lenticular lens element thus constructed is optically polished by a conventional method. In the result of testing the lenticular lens installed as mentioned above, the gain of 2.5 or more and the efficiency of 79% were measured. These measurements were obtained in a sufficiently diffused state so as to obtain a predetermined half value intensity in the direction of +9.5 degrees perpendicular to the direction of the peak intensity. In addition, although the vertical observation surface increases the diffusion again and can be enlarged by adding and combining the lenticular lens array in the horizontal direction, the corresponding loss occurs in the screen gain.

Such a lenticular lens array device is preferably manufactured by a high performance tool such as a diamond turning lathe and a diamond tool, and the working limit is an important consideration. Only slight deviations in dimensions are allowed, and the shape of the entire lenticular lens, such as the pitch-to-height ratio and the pitch-to-tip width ratio, or the inner reflecting side and the refractive tip surface, is a major factor in determining the characteristics.

Although the present invention has been described in detail with respect to the specific embodiments described above, modifications and variations from the above embodiments can be made by those skilled in the art. Accordingly, the invention is limited only by the scope of the claimed claims.

Claims (12)

In order to deflect the light rays received from the image source, respectively, to display the image with a substantially uniform brightness over a wide viewing angle, at least a part of the base portion, the first side portion 34 and the second side portion 36, and the base portion are opposed to each other. A rear projection screen composed of one tip portion 38 and generally provided with a light diffusing means on the front surface 30 having a plurality of lenticular lenses 32 closely arranged in parallel with each other, wherein the first side portion is An average slope of 43 ° to 85 ° relative to the base, the second side having an average slope of 43 ° to 85 ° relative to the base, and an average slope of the first and second sides The two sides are selected to reflect substantially internally, and the ratio of the height of the lenticular lens to the width of the base is greater than 1: 1, and the ratio of the width of the base to the width of the tip is greater than 2: 1. Tip part 38 is continuous with the first and second side portions, and is composed of two convex cylindrical portions 40 and 44 and a central concave cylindrical portion 42 having a substantially refractive power. Projection screen. 2. A rear projection screen according to claim 1, wherein all of the plurality of lenticular lenses (32) closely arranged in parallel with each other have the same configuration. The rear projection screen according to claim 2, wherein the first average slope and the second average slope are each greater than 70 degrees. 4. The rear projection screen of claim 3, wherein the first average slope and the second average slope are substantially equal. 2. The rear projection screen of claim 1, wherein the two convex cylindrical portions (40,44) and the concave cylindrical portions (42) have substantially the same radius. 6. The rear projection screen according to claim 5, wherein the lenticular lens (32) is symmetrically disposed about a central axis extending perpendicular to the base portion. The rear projection screen according to claim 1, wherein the ratio of the height of the lenticular lens to the width of the base portion is larger than 3: 2. 8. The rear projection screen of claim 7, wherein the ratio of the width of the base portion to the width of the tip portion is greater than 3: 1. The symmetric lens according to claim 6, wherein the first side portion, the second side portion and the tip portion are substantially proportional to a lenticular lens defined symmetrically with respect to X = 0.275 mm because the width of the base portion is equal to 0.55 mm. Each side of is composed of 397 segment segments whose slopes are defined by

The end of the 397th segment is located at the coordinate point X ₃₉₈ = 0.21310, Y ₃₉₈ = 0.00438, X <0.21310 and Xi≤X <Xi

The shape of the first side part is determined by interpolation method Y = Yi + (X-Xi) × Mi + D with respect to X provided as ₁ , and the shape of the first side part is determined by interpolation method of 0.21310 ≦ X <D. For X in the range of 0.21310? X <0.25735, the shape of the tip is Y = -SQRT [R²- (X-XO₁) ²] + YO₁, where XO₁ = 0.23971mm YO₁ = 0.86896mm And a circle of R = 0.03076 mm, and for the range of X in 0.25735≤X <0.2750, in the formula that the shape of the tip is Y = + SQRT [R²- (X-XO₂) ²] + YO₂, By defining it as a circle with XO₂ = 0.22750mm, YO₂ = 0.91936mm and R = 0.03076mm, the values of the coordinates Y are all greater than or equal to 0, and the ribs at the tip portions are continuous of the slopes of the coordinates Y and Y A rear projection screen characterized in that it is specified as a function. The lenticular lens 32 disposed in parallel with each other defines each groove 46 mutually, and the screen has absorbing means 43 disposed in the groove to absorb visible light, The absorbing means (43) is provided with a large amount of light absorber particles to reduce the reflection of visible light penetrating the screen, characterized in that the rear projection screen. A rear projection screen according to claim 10, comprising means (50) for containing said light absorber particles in said groove. 2. The apparatus according to claim 1, further comprising: on the back portion of the screen, an optical parallel focusing means for receiving diverging mines from an image projector and converging the diverging rays into parallel beams for displaying an image to be displayed by the screen. Rear projection screen featuring.

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